DE2425647B2 - Sensor for CO2 measuring device - Google Patents

Description

25th

The invention relates to a sensor for CO ₂ measuring devices in the form of a cell which contains a small amount of deionized water and has at least one J0 membrane made of a semipermeable material, which on one side with the gas mixture to be measured and on its other side with the deionized water is in contact, as well as two J5 electrodes to be connected to an electrical measuring instrument and a granular ion exchanger.

Carbon dioxide is a breath poison which can cause serious damage to health if inhaled. To prevent this, the concentration in the breath must be monitored. The list with the »maximum workplace concentrations (MAK value)« only allows a maximum value of 5000 ppm for CO2 in the air at the workplace. In medicine, there are so-called breathing circuit systems to which the patients are connected for various purposes. The patient takes oxygen from the air he breathe, while he releases CO2 into the system when he breathes out. The extracted oxygen is replenished from the outside, the carbon dioxide removed by devices through which the breathing air in the breathing circuit system is passed. The air can only be breathed as long as the O ₂ content is sufficient and the CO2 content does not exceed a certain value.

A gas measuring device is known in which the CCV content can be measured in rooms in which the gas is fed into a conductivity cell filled with a liquid. The cell is in front of the Measurement filled with a liquid from a storage container and emptied again when the measurement is carried out. The liquid flows from the cell via an ion exchanger into the storage container return. The control of the measuring process, with filling the liquid, introducing the gas and Measure the conductivity of the liquid, then empty the cell and return the Liquid via the ion exchanger into the storage tank is carried out by an automatic control system.

The gas meter for CO ₂ is, due to the necessary liquid flow, with the ion exchanger switched into the circuit and the pump system with the automatic control, very extensive and correspondingly complicated. It can only be used stationary because the liquid flow only works in the vertical. The measured values can only be obtained discontinuously in accordance with the liquid cycle (US Pat. No. 3,544,278).

Another known CO ₂ measuring device differs from the one mentioned above in that the water circulates continuously in the measuring cell and ion exchanger arrangement. The gas mixture containing the CO ₂ to be measured is pressed into the deionized water leaving the ion exchanger at the lower end of a tube and rises in bubbles under the effect of buoyancy inside the tube until it enters the measuring cell at the upper end. As a result of this upward movement of the gas bubbles, the water is circulated through the ion exchanger and the measuring cell. The water in the measuring cell is constantly renewed. The connected measuring instrument continuously shows every instantaneous value. However, the device is bound to a vertical installation and is therefore stationary. It cannot be used as a handheld device (GB-PS 11 43 403).

Furthermore, a CO2 warning device has been proposed which contains demineralized water as electrolyte in a measuring cell and which, after the reaction has taken place, can be regenerated as required using a small supply of ion exchanger (mixed bed filter) substance located in the device. The gas exchange in the measuring cell takes place via a gas-permeable membrane. The measuring cell is arranged in the gas flow to be measured. So that the gas exchange process through the membrane reaches a final value as quickly as possible, the measuring cell is small and therefore only contains a small amount of the desalinated water. The water is exchanged by actuating a pump mechanism, such as a normal injection syringe, which is accessible from the outside. The proposed CO ₂ measuring device can be made small due to the measuring cell brought into the gas flow with the small amount of electrolytes; However, here too there is a discontinuous measurement with a position-dependent device (DE-OS 16 48 989).

In an addition to the CO2 measuring device proposed above, a device for monitoring the CO ₂ concentration in the gas mixture to be supplied to a patient for inhalation anesthesia is proposed, in which a very small cell filled with deionized water is arranged in the tube carrying the anesthetic gas mixture which contains a gas-permeable membrane and in which the mass of an ion exchanger is arranged. The first electrode is located in the space filled with the electrolyte between the membrane and the ion exchanger and the second electrode is either in the same space between the first electrode or embedded in the bulk of the ion exchanger (DE-OS 21 47 718).

The invention is based on the _{object of creating a sensor for a CO 2 measuring device, which measures the CO 2} concentration present in the test gas at any time with a short rise and fall time, is small and robust, functions independently of the position and thus works together with the display device and the power source as

portable measuring device can be used.

This object is achieved according to the invention in that the first electrode on the inside of the membrane, the second electrode is arranged on the opposite wall of the cell and the space between the two electrodes is filled with the granular ion exchanger.

This solution creates a sensor with a very compact design. Because the decisive Components fit closely to one another without gaps, these are in the order in which they are listed the membrane, the first electrode, the granular ionizer, and the second electrode, result in short slopes Fall times for the individual measurements. Due to the possible fixed assembly with small ones At intervals, the cell fluid no longer shifts during handling. So they are Measured values of the sensor extremely stable.

Due to the direct contact between the ion exchange grains If the internal resistance of the cell is reduced, it does not occur at all a short circuit; because the (onenaustauscherkörner only have moderate electrical conductivity. The correspondingly low sensitivity plays a role for the planned use for measuring CO2 does not matter, it is still completely sufficient. They are decisive Advantages from the shorter rise and fall times during the measurement and the high stability of the measured value.

In an embodiment of the invention, the granular ion exchanger forms the second electrode. At this Arrangement acts the granular ion exchanger, which has a certain conductivity in the swollen state, even as a second electrode. The electrical connection is made in front of a pressed screen. In In this embodiment, the rise and fall times reach minimum values.

According to a development, the first electrode is a metal layer vapor-deposited on the membrane. This advantageous design makes the structure even more compact and enables very safe installation of the Ion exchange grains on the first electrode with simple assembly.

An embodiment of the invention is shown schematically in the drawing and is in described in more detail below. It shows

F i g. ι the structure of the sensor

Fig. 2 shows the circuit structure of a CCV measuring device with the sensor according to FIG. 1.

The sensor of FIG. 1 contains the two electrodes 2 and 3 in a cell 1 made of plastic. The space in between is filled with the granular ion exchanger 4. The cell 1 is covered by the membrane 5, the ring 6 keeps it taut and close to the cell wall 7. To ensure a tight and stable packing of the electrodes 2 and 3 and the ion exchanger 4 in the cell 1 and to ensure a tightly fitting membrane 5 is over the cell 1 has a cap 8 placed over it which, with a compression spring 9, forms a gas-permeable sintered body 10 presses against the membrane 5. The cap 8 has holes 11 in the end face for the passage of gas.

The electrodes 23 have liquid-tight connections through the cell wall, the first electrode 2 the connection 12 and the second electrode 3 the connection 13. The remaining cavities in the cell 1 are filled with deionized water. In the wall 20 of the cell 1 there is an NTC resistor 14 serves for temperature compensation.

The dimensions of the sensor according to the example do not exceed the values 25 mm 0 χ 15 mm Height. FIG. 2 shows the circuit structure of a CCV measuring device with the sensor according to FIG Sensor 15 is supplied by an alternating current source 16. It is with the connections 12 and 13 of the Electrodes connected. In one connection line 17 is the measuring instrument 18 with the measuring resistor 19. To compensate for temperature influences on the display caused by different permeability the membrane can be caused, the NTC resistor 14 of the measuring connection line 17 is connected in parallel.

For this purpose 2 sheets of drawings

Claims (3)

Patent claims: 1. Sensor for CO ₂ measuring devices in the form of a cell that contains a small amount of deionized water and has at least one membrane made of a semipermeable material, which on one side with the gas mixture to be measured and on its other side with the ionized water in Contact is, and contains two electrodes to be connected to an electrical measuring instrument and a granular ion exchanger, characterized in that the first electrode (2) on the inside of the membrane (5), the second electrode (3) on the opposite wall (20) the cell is arranged and the space between the two electrodes (2, 3) is filled with the granular ion exchanger (4). 2. Sensor according to claim 1, characterized in that the granular ion exchanger (4) is the second Electrode forms. 3. Sensor according to claim 1 and 2, characterized in that the first electrode (2) has one the membrane (5) is a vapor-deposited metal layer.